Building-information management system with directional wind propagation and diffusion

ABSTRACT

A building-information management (BIM) system receives a set of wind vectors that identify wind speeds and directions at the surfaces of physical structures within a volume of air. The system stratifies the volume into vertically stacked layers that each contains similar wind vectors. Each layer is then divided horizontally into rectangular cells that each at least partially encloses a cluster of the structures. The system infers cell-specific relationships that relate physical attributes of the enclosed structures with the cell&#39;s incoming and outgoing airflows, from which the system builds a wind-propagation model for each cell. These cell-specific models are combined into a regional wind-propagation model that predicts how winds entering the volume will be propagated as outgoing wind vectors. The regional model is used by downstream modules of the BIM system to account for airflow effects when designing a planned building.

BACKGROUND

The present invention relates generally to urban planning and to otherfields that incorporate principles of architectural design, and relatesspecifically to improving BIM (Building-information management)architectural-design systems to intelligently account for external andinternal air flows during the design of one or more buildings.

Unlike older two-dimensional blueprint-based architectural-designmethodologies and three-dimensional computerized CAD systems, BIMapplications may augment the three spatial dimensions of a 3D buildingplan with time as a fourth dimension (a 4D plan) or cost as a fifthdimension (a 5D plan). BIM applications, for example, may account forspatial relationships, light analysis, geographic information, budgetingconstraints, materials costs, voids and air spaces between physicalobjects, and component specifications. Therefore, instead of merelyproviding a two-dimensional drawing or three-dimensional physical modelof buildings, BIM technology creates intelligent “virtual informationmodels” that may be used by architects, surveyors, civil engineers,urban planners, and other architectural professionals to direct theactivities of general contractors and construction specialists.

One drawback of current BIM systems is an inability to account forinternal and external airflows when designing physical structures. Whendetermining the location and physical properties of a building, it isimportant to account for the magnitudes and directions of such externalair flows, such as the horizontal and vertical velocity and directionalcharacteristics of environmental air movement. Such considerations maybe necessary, for example, in order to effectively design and distributea building's air ducts and internal ventilation systems, and to optimizethe building's physical effects on its environment, such as thebuilding's effect on the natural dispersal of environmental pollutantsor the building's effect on channeling wind vectors throughout theimmediate neighborhood.

Current BIM systems do not effectively account for such factors. Knownmethods may at best roughly approximate air flow parameters as afunction of non-directional particle diffusion, which do not predict,analyze, or simulate directional diffusion characteristics, such ashorizontal and vertical wind-speed vectors. Furthermore, because theminimal airflow-analysis functionality of known automatedbuilding-design systems use principles of aerodynamics and basicgeometry to analyze and model air flows, these known systems requirecomplex, resource-intensive procedures in order to derive evenrelatively simple approximations.

SUMMARY

An embodiment of the present invention is a building-informationmanagement system comprising a processor, a memory coupled to theprocessor, and a computer-readable hardware storage device coupled tothe processor, the storage device containing program code configured tobe run by the processor via the memory to implement a method for abuilding-information management system with directional wind propagationand diffusion, the method comprising:

the processor receiving a set of wind vectors that have been measuredconcurrently at a set of measurement points located within a volume ofair, where each wind vector of the set of wind vectors specifies a valueof a horizontal wind speed at a corresponding measurement point of theset of measurement points and a value of a horizontal wind direction atthe corresponding measurement point;

the processor stratifying the volume of air into a vertical stack ofcontiguous, non-overlapping horizontal layers, where each layer of thestack extends through a contiguous range of vertical heights andencompasses a subset of the set of measurement points measured atheights within that layer's range of vertical heights;

the processor retrieving a set of building attributes that identifylocations and physical dimensions of buildings located within the volumeof space;

the processor dividing each layer of the horizontal layers into ahorizontal grid of rectangular cells, where a first cell of a firstlayer of the horizontal layers encloses horizontal cross-sections of afirst subset of the buildings at heights within the first layer's rangeof vertical heights;

the processor selecting, as a function of those received wind vectorsthat were measured at measurement points comprised by the first cell, aninput wind speed of the first cell in each horizontal wind direction andan output wind speed of the first cell in each horizontal winddirection, where each horizontal wind direction is selected from thegroup consisting of northerly, southerly, easterly, and westerly;

the processor inferring relationships between wind-speed decay rates ofhorizontal winds flowing through the first cell and retrieved attributesof buildings that are at least partially enclosed by the first cell; and

the processor forwarding to downstream modules of thebuilding-information management system a wind-propagation model of thevolume of space that identifies, as a function of the inferredrelationships, rules for determining wind vectors of winds exiting thevolume as functions of wind vectors of winds entering the volume.

Another embodiment of the present invention is a method for abuilding-information management system with directional wind propagationand diffusion, the method comprising:

a processor of the building-information management system receiving aset of wind vectors that have been measured concurrently at a set ofmeasurement points located within a volume of air, where each windvector of the set of wind vectors specifies a value of a horizontal windspeed at a corresponding measurement point of the set of measurementpoints and a value of a horizontal wind direction at the correspondingmeasurement point;

the processor stratifying the volume of air into a vertical stack ofcontiguous, non-overlapping horizontal layers, where each layer of thestack extends through a contiguous range of vertical heights andencompasses a subset of the set of measurement points measured atheights within that layer's range of vertical heights;

the processor retrieving a set of building attributes that identifylocations and physical dimensions of buildings located within the volumeof space;

the processor dividing each layer of the horizontal layers into ahorizontal grid of rectangular cells, where a first cell of a firstlayer of the horizontal layers encloses horizontal cross-sections of afirst subset of the buildings at heights within the first layer's rangeof vertical heights;

the processor selecting, as a function of those received wind vectorsthat were measured at measurement points comprised by the first cell, aninput wind speed of the first cell in each horizontal wind direction andan output wind speed of the first cell in each horizontal winddirection, where each horizontal wind direction is selected from thegroup consisting of northerly, southerly, easterly, and westerly;

the processor inferring relationships between wind-speed decay rates ofhorizontal winds flowing through the first cell and retrieved attributesof buildings that are at least partially enclosed by the first cell; and

the processor forwarding to downstream modules of thebuilding-information management system a wind-propagation model of thevolume of space that identifies, as a function of the inferredrelationships, rules for determining wind vectors of winds exiting thevolume as functions of wind vectors of winds entering the volume.

Yet another embodiment of the present invention is a computer programproduct, comprising a computer-readable hardware storage device having acomputer-readable program code stored therein, the program codeconfigured to be executed by a building-information management systemcomprising a processor, a memory coupled to the processor, and acomputer-readable hardware storage device coupled to the processor, thestorage device containing program code configured to be run by theprocessor via the memory to implement a method for abuilding-information management system with directional wind propagationand diffusion, the method comprising:

the processor receiving a set of wind vectors that have been measuredconcurrently at a set of measurement points located within a volume ofair, where each wind vector of the set of wind vectors specifies a valueof a horizontal wind speed at a corresponding measurement point of theset of measurement points and a value of a horizontal wind direction atthe corresponding measurement point;

the processor stratifying the volume of air into a vertical stack ofcontiguous, non-overlapping horizontal layers, where each layer of thestack extends through a contiguous range of vertical heights andencompasses a subset of the set of measurement points measured atheights within that layer's range of vertical heights;

the processor retrieving a set of building attributes that identifylocations and physical dimensions of buildings located within the volumeof space;

the processor dividing each layer of the horizontal layers into ahorizontal grid of rectangular cells, where a first cell of a firstlayer of the horizontal layers encloses horizontal cross-sections of afirst subset of the buildings at heights within the first layer's rangeof vertical heights;

the processor selecting, as a function of those received wind vectorsthat were measured at measurement points comprised by the first cell, aninput wind speed of the first cell in each horizontal wind direction andan output wind speed of the first cell in each horizontal winddirection, where each horizontal wind direction is selected from thegroup consisting of northerly, southerly, easterly, and westerly;

the processor inferring relationships between wind-speed decay rates ofhorizontal winds flowing through the first cell and retrieved attributesof buildings that are at least partially enclosed by the first cell; and

the processor forwarding to downstream modules of thebuilding-information management system a wind-propagation model of thevolume of space that identifies, as a function of the inferredrelationships, rules for determining wind vectors of winds exiting thevolume as functions of wind vectors of winds entering the volume.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows the general structure of a computer system and computerprogram code that may be used to implement a method forbuilding-information management system with directional wind propagationand diffusion in accordance with embodiments of the present invention.

FIG. 2 shows a more specific or implementing a building-informationmanagement system with directional wind propagation and diffusion inaccordance with embodiments of the present invention.

FIG. 3 is a flow chart that illustrates steps of a method forbuilding-information management system with directional wind propagationand diffusion in accordance with embodiments of the present invention.

FIG. 4 is a flow chart that illustrates steps for vertical spatialstratification of a volume of space into a vertical stack of horizontallayers by an improved building-information management system inaccordance with embodiments of the present invention.

FIG. 5 is a flow chart that illustrates steps for partitioning apreviously generated horizontal layer in accordance with embodiments ofthe present invention.

FIG. 6 is a flow chart that illustrates steps for generating propagationand diffusion values for cells and layers of a previously generatedhorizontal layer in accordance with embodiments of the presentinvention.

FIG. 7 is a flow chart that illustrates steps for aggregatingpropagation and diffusion values for each horizontal layer of a volumeof space into a regional airflow model of the entire volume, inaccordance with embodiments of the present invention.

DETAILED DESCRIPTION

The present invention comprises systems, methods, and computer programproducts for improving current automated BIM systems with the ability tosimulate and derive directional characteristics of external airflows,such as the speed, direction, propagation and decay rates, and diffusioncharacteristics of wind currents. Systems 200 that comprise suchimproved BIM technologies can then use this information, when generating4D or 5D models 240 of planned buildings, infrastructure, orneighborhoods within a three-dimensional volume of space, in order tobetter account for interactions between the external airflows and theplanned buildings or infrastructure.

The present invention further improves known BIM systems by allowingsuch systems to quantify complex directional diffusion parameters atlow, near-ground altitudes, and to represent wind speeds, winddirections, and geographical information as vector indices. Theseimprovements also allow an airflow-analysis module 210 of the improvedBIM system 200 to account for airflow, diffusion, and ventilationcharacteristics of specific classes of geographical environment, such asgrasslands, lakes, or building-dense urban neighborhoods.

The present invention performs these tasks by using properties of windspeed and direction measurements sampled concurrently throughout thethree-dimensional volume of space to vertically stratify the volume intolayers, and to then subdivide each layer into a layer-specific grid ofcells.

These tasks, performed by means of the four-stage procedure shown inFIG. 3 and elaborated in subsequent figures, improves known BIMtechnology by solving a previously unsolved technical problem in amanner that is not well-understood, routine, or conventional in thefields of building-information management, architectural design, civilengineering, HVAC design, or related fields.

The present invention may be a system, a method, and/or a computerprogram product at any possible technical detail level of integration.The computer program product may include a computer readable storagemedium (or media) having computer readable program instructions thereonfor causing a processor to carry out aspects of the present invention.

The computer readable storage medium can be a tangible device that canretain and store instructions for use by an instruction executiondevice. The computer readable storage medium may be, for example, but isnot limited to, an electronic storage device, a magnetic storage device,an optical storage device, an electromagnetic storage device, asemiconductor storage device, or any suitable combination of theforegoing. A non-exhaustive list of more specific examples of thecomputer readable storage medium includes the following: a portablecomputer diskette, a hard disk, a random access memory (RAM), aread-only memory (ROM), an erasable programmable read-only memory (EPROMor Flash memory), a static random access memory (SRAM), a portablecompact disc read-only memory (CD-ROM), a digital versatile disk (DVD),a memory stick, a floppy disk, a mechanically encoded device such aspunch-cards or raised structures in a groove having instructionsrecorded thereon, and any suitable combination of the foregoing. Acomputer readable storage medium, as used herein, is not to be construedas being transitory signals per se, such as radio waves or other freelypropagating electromagnetic waves, electromagnetic waves propagatingthrough a waveguide or other transmission media (e.g., light pulsespassing through a fiber-optic cable), or electrical signals transmittedthrough a wire.

Computer readable program instructions described herein can bedownloaded to respective computing/processing devices from a computerreadable storage medium or to an external computer or external storagedevice via a network, for example, the Internet, a local area network, awide area network and/or a wireless network. The network may comprisecopper transmission cables, optical transmission fibers, wirelesstransmission, routers, firewalls, switches, gateway computers and/oredge servers. A network adapter card or network interface in eachcomputing/processing device receives computer readable programinstructions from the network and forwards the computer readable programinstructions for storage in a computer readable storage medium withinthe respective computing/processing device.

Computer readable program instructions for carrying out operations ofthe present invention may be assembler instructions,instruction-set-architecture (ISA) instructions, machine instructions,machine dependent instructions, microcode, firmware instructions,state-setting data, configuration data for integrated circuitry, oreither source code or object code written in any combination of one ormore programming languages, including an object oriented programminglanguage such as Smalltalk, C++, or the like, and procedural programminglanguages, such as the “C” programming language or similar programminglanguages. The computer readable program instructions may executeentirely on the user's computer, partly on the user's computer, as astand-alone software package, partly on the user's computer and partlyon a remote computer or entirely on the remote computer or server. Inthe latter scenario, the remote computer may be connected to the user'scomputer through any type of network, including a local area network(LAN) or a wide area network (WAN), or the connection may be made to anexternal computer (for example, through the Internet using an InternetService Provider). In some embodiments, electronic circuitry including,for example, programmable logic circuitry, field-programmable gatearrays (FPGA), or programmable logic arrays (PLA) may execute thecomputer readable program instructions by utilizing state information ofthe computer readable program instructions to personalize the electroniccircuitry, in order to perform aspects of the present invention.

Aspects of the present invention are described herein with reference toflowchart illustrations and/or block diagrams of methods, apparatus(systems), and computer program products according to embodiments of theinvention. It will be understood that each block of the flowchartillustrations and/or block diagrams, and combinations of blocks in theflowchart illustrations and/or block diagrams, can be implemented bycomputer readable program instructions.

These computer readable program instructions may be provided to aprocessor of a general purpose computer, special purpose computer, orother programmable data processing apparatus to produce a machine, suchthat the instructions, which execute via the processor of the computeror other programmable data processing apparatus, create means forimplementing the functions/acts specified in the flowchart and/or blockdiagram block or blocks. These computer readable program instructionsmay also be stored in a computer readable storage medium that can directa computer, a programmable data processing apparatus, and/or otherdevices to function in a particular manner, such that the computerreadable storage medium having instructions stored therein comprises anarticle of manufacture including instructions which implement aspects ofthe function/act specified in the flowchart and/or block diagram blockor blocks.

The computer readable program instructions may also be loaded onto acomputer, other programmable data processing apparatus, or other deviceto cause a series of operational steps to be performed on the computer,other programmable apparatus or other device to produce a computerimplemented process, such that the instructions which execute on thecomputer, other programmable apparatus, or other device implement thefunctions/acts specified in the flowchart and/or block diagram block orblocks.

The flowchart and block diagrams in the Figures illustrate thearchitecture, functionality, and operation of possible implementationsof systems, methods, and computer program products according to variousembodiments of the present invention. In this regard, each block in theflowchart or block diagrams may represent a module, segment, or portionof instructions, which comprises one or more executable instructions forimplementing the specified logical function(s). In some alternativeimplementations, the functions noted in the blocks may occur out of theorder noted in the Figures. For example, two blocks shown in successionmay, in fact, be executed substantially concurrently, or the blocks maysometimes be executed in the reverse order, depending upon thefunctionality involved. It will also be noted that each block of theblock diagrams and/or flowchart illustration, and combinations of blocksin the block diagrams and/or flowchart illustration, can be implementedby special purpose hardware-based systems that perform the specifiedfunctions or acts or carry out combinations of special purpose hardwareand computer instructions.

FIG. 1 shows a structure of a computer system and computer program codethat may be used to implement a method for building-informationmanagement system with directional wind propagation and diffusion inaccordance with embodiments of the present invention. FIG. 1 refers toobjects 101-115.

In FIG. 1, computer system 101 comprises a processor 103 coupled throughone or more I/O Interfaces 109 to one or more hardware data storagedevices 111 and one or more I/O devices 113 and 115.

Hardware data storage devices 111 may include, but are not limited to,magnetic tape drives, fixed or removable hard disks, optical discs,storage-equipped mobile devices, and solid-state random-access orread-only storage devices. I/O devices may comprise, but are not limitedto: input devices 113, such as keyboards, scanners, handheldtelecommunications devices, touch-sensitive displays, tablets, biometricreaders, joysticks, trackballs, or computer mice; and output devices115, which may comprise, but are not limited to printers, plotters,tablets, mobile telephones, displays, or sound-producing devices. Datastorage devices 111, input devices 113, and output devices 115 may belocated either locally or at remote sites from which they are connectedto I/O Interface 109 through a network interface.

Processor 103 may also be connected to one or more memory devices 105,which may include, but are not limited to, Dynamic RAM (DRAM), StaticRAM (SRAM), Programmable Read-Only Memory (PROM), Field-ProgrammableGate Arrays (FPGA), Secure Digital memory cards, SIM cards, or othertypes of memory devices.

At least one memory device 105 contains stored computer program code107, which is a computer program that comprises computer-executableinstructions. The stored computer program code includes a program thatimplements a method for building-information management system withdirectional wind propagation and diffusion in accordance withembodiments of the present invention, and may implement otherembodiments described in this specification, including the methodsillustrated in FIGS. 1-7. The data storage devices 111 may store thecomputer program code 107. Computer program code 107 stored in thestorage devices 111 is configured to be executed by processor 103 viathe memory devices 105. Processor 103 executes the stored computerprogram code 107.

In some embodiments, rather than being stored and accessed from a harddrive, optical disc or other writeable, rewriteable, or removablehardware data-storage device 111, stored computer program code 107 maybe stored on a static, nonremovable, read-only storage medium such as aRead-Only Memory (ROM) device 105, or may be accessed by processor 103directly from such a static, nonremovable, read-only medium 105.Similarly, in some embodiments, stored computer program code 107 may bestored as computer-readable firmware 105, or may be accessed byprocessor 103 directly from such firmware 105, rather than from a moredynamic or removable hardware data-storage device 111, such as a harddrive or optical disc.

Thus the present invention discloses a process for supporting computerinfrastructure, integrating, hosting, maintaining, and deployingcomputer-readable code into the computer system 101, wherein the code incombination with the computer system 101 is capable of performing amethod for building-information management system with directional windpropagation and diffusion.

Any of the components of the present invention could be created,integrated, hosted, maintained, deployed, managed, serviced, supported,etc. by a service provider who offers to facilitate a method forbuilding-information management system with directional wind propagationand diffusion. Thus the present invention discloses a process fordeploying or integrating computing infrastructure, comprisingintegrating computer-readable code into the computer system 101, whereinthe code in combination with the computer system 101 is capable ofperforming a method for building-information management system withdirectional wind propagation and diffusion.

One or more data storage units 111 (or one or more additional memorydevices not shown in FIG. 1) may be used as a computer-readable hardwarestorage device having a computer-readable program embodied thereinand/or having other data stored therein, wherein the computer-readableprogram comprises stored computer program code 107. Generally, acomputer program product (or, alternatively, an article of manufacture)of computer system 101 may comprise the computer-readable hardwarestorage device.

In embodiments that comprise components of a networked computinginfrastructure, a cloud-computing environment, a client-serverarchitecture, or other types of distributed platforms, functionality ofthe present invention may be implemented solely on a client or userdevice, may be implemented solely on a remote server or as a service ofa cloud-computing platform, or may be split between local and remotecomponents.

While it is understood that program code 107 for a method forbuilding-information management system with directional wind propagationand diffusion may be deployed by manually loading the program code 107directly into client, server, and proxy computers (not shown) by loadingthe program code 107 into a computer-readable storage medium (e.g.,computer data storage device 111), program code 107 may also beautomatically or semi-automatically deployed into computer system 101 bysending program code 107 to a central server (e.g., computer system 101)or to a group of central servers. Program code 107 may then bedownloaded into client computers (not shown) that will execute programcode 107.

Alternatively, program code 107 may be sent directly to the clientcomputer via e-mail. Program code 107 may then either be detached to adirectory on the client computer or loaded into a directory on theclient computer by an e-mail option that selects a program that detachesprogram code 107 into the directory.

Another alternative is to send program code 107 directly to a directoryon the client computer hard drive. If proxy servers are configured, theprocess selects the proxy server code, determines on which computers toplace the proxy servers' code, transmits the proxy server code, and theninstalls the proxy server code on the proxy computer. Program code 107is then transmitted to the proxy server and stored on the proxy server.

In one embodiment, program code 107 for a method forbuilding-information management system with directional wind propagationand diffusion is integrated into a client, server and networkenvironment by providing for program code 107 to coexist with softwareapplications (not shown), operating systems (not shown) and networkoperating systems software (not shown) and then installing program code107 on the clients and servers in the environment where program code 107will function.

The first step of the aforementioned integration of code included inprogram code 107 is to identify any software on the clients and servers,including the network operating system (not shown), where program code107 will be deployed that are required by program code 107 or that workin conjunction with program code 107. This identified software includesthe network operating system, where the network operating systemcomprises software that enhances a basic operating system by addingnetworking features. Next, the software applications and version numbersare identified and compared to a list of software applications andcorrect version numbers that have been tested to work with program code107. A software application that is missing or that does not match acorrect version number is upgraded to the correct version.

A program instruction that passes parameters from program code 107 to asoftware application is checked to ensure that the instruction'sparameter list matches a parameter list required by the program code107. Conversely, a parameter passed by the software application toprogram code 107 is checked to ensure that the parameter matches aparameter required by program code 107. The client and server operatingsystems, including the network operating systems, are identified andcompared to a list of operating systems, version numbers, and networksoftware programs that have been tested to work with program code 107.An operating system, version number, or network software program thatdoes not match an entry of the list of tested operating systems andversion numbers is upgraded to the listed level on the client computersand upgraded to the listed level on the server computers.

After ensuring that the software, where program code 107 is to bedeployed, is at a correct version level that has been tested to workwith program code 107, the integration is completed by installingprogram code 107 on the clients and servers.

Embodiments of the present invention may be implemented as a methodperformed by a processor of a computer system, as a computer programproduct, as a computer system, or as a processor-performed process orservice for supporting computer infrastructure.

FIG. 2 shows a more specific architecture of a building-informationmanagement system with directional wind propagation and diffusion inaccordance with embodiments of the present invention. FIG. 2 showselements identified by reference numbers 200-240.

Item 200 is an improved Building Information System (BIM) that isenhanced, in accordance with embodiments of the present invention, withthe ability to generate a 4D or 5D plan or model 240 for one or morebuildings that accounts for directional air flows.

Items 212-230 are modules of BIM 200.

Item 210 is an airflow-analysis module that analyzes and models theinteractions between external airflows and planned buildings orinfrastructure represented in the plan 240. Item 210 performs thisoperation by means of methods described in FIGS. 3-7.

Analysis module 210 performs these operations as functions ofinformation read from a measurements database 212, which stores sets ofconcurrently sampled empirical measurements of wind velocity anddirection vectors (v,d) at points throughout the volume of space beinganalyzed, and an attributes database 214 that stores information aboutphysical structures, and other physical entities capable of affectingairflow patterns, located within the volume of space. In someembodiments, the volume of space must be a volume of air, but otherembodiments may comprise volumes of space are not volumes of air.

Item 220 comprises one or more design modules of BIM 200. These designmodules 220 receive airflow parameters developed by item 210 andincorporate that information into the BIM model 240.

Item 230 is an output module of BIM 200. Using algorithmic methods thatare known or algorithmic methods analogous to methods that are known inthe art of building information systems, output module 230 generates BIMplan or model 240.

Building information model 240 is an intelligent model of one or moreplanned buildings or infrastructures, which may be forwarded todownstream software systems or applications, or which may be used togenerate directions or plans for downstream professionals, such ascontractors, civil engineers, licensing entities, or architecturalspecialists.

FIG. 3 is a flow chart that illustrates steps of a method for animproved building-information management system 200 with analysis ofdirectional wind propagation and directional wind diffusion inaccordance with embodiments of the present invention. FIG. 3 containssteps 300-360, which may be performed by embodiments that incorporatecomponents and topologies of FIGS. 1 and 2.

In step 300, an airflow-analysis module 210 of an improved BIM 200stratifies the volume of space into which the planned buildings orinfrastructure will be built, into a set of horizontal layers. Eachlayer consists of a set of similar cross-sections of a subset of thevolume, where each cross-section is characterized by a height, avertical airflow (or wind) speed, and a direction of thatcross-section's vertical airflow. Two cross-sections are deemed to besimilar enough to be included in a same layer if the two cross-sectionalareas are associated with similar airflow directions and similar airflowspeeds, when airflow directions and airflow speeds are measuredthroughout the volume of space during a duration time short enough toensure that the measured values are likely to persist throughout thevolume concurrently.

A layer may contain cross-sections that are located at differentheights, and the overall “height” of the layer is defined as thevertical distance between the layer's highest area and the layer'slowest area. Regardless of their heights, however, all areas of a singlelayer must identify similar vertical airflow directions and similarairflow speeds. This procedure is described in greater detail in FIG. 4.

In step 310, the analysis module 210 divides each layer into a grid ofcells. Each grid of a particular layer contains rectangular cells ofvarious dimensions and aspect ratios that are selected as a function ofvariations in the density of buildings and other physical structureswithin the height range of the layer. This factor is important becausethe presence of a physical structure can significantly affect thepropagation and diffusion of proximate airflows. Each cell of aparticular layer is thus a three-dimensional volume that defines acontiguous rectangular area of the layer's horizontal (xy) cross-sectionand that has a height along the z axis equal to the height of the layer.Each cell contains wind measurements that have similar wind speed/winddirection values and that were measured at points characterized by thespecific building density associated with all coordinate points withinthat cell. This procedure is described in greater detail in FIG. 5.

In step 320, analysis module 210 derives a ventilation model for eachcell. Each model identifies the direction and speed of that cell'saggregate input airflow and output airflow. This procedure is describedin greater detail in FIG. 6, steps 600-650.

In step 330, analysis module 210 merges the resulting set of windvectors for each horizontal layer, to generate generates a set oftime-varying wind-propagation and diffusion values for each layer. Thisprocedure is described in greater detail in FIG. 6, step 660.

In step 340, analysis module 210 uses the previously derived propagationand diffusion values to determine a time-varying “regional pattern” ofwind-propagation and dispersion for the entire volume of air. Thisprocedure is described in greater detail in FIG. 7.

In step 350, analysis module 210, through technical means analogous tothose of current BIM systems, forwards a model of the regional patternof airflow propagation and dispersion to design module 220 of BIM 200.The design module then, through methods and technologies known in theart, uses this forwarded information to revise the system's 4D or 5D BIMmodel in order to better select physical properties, locations, andorientations of each planned building or infrastructure component withinthe volume of air, or to better configure each planned building orinfrastructure component's internal and external airflows, such as byconfiguring an HVAC system, ductwork, or external vents.

In step 360, output module 230 of BIM 200 outputs the final 4D or 5Dmodel in forms that may be viewed, analyzed, or interactively revised bydownstream users, or in forms that may be received as input bydownstream systems. This procedure may be performed by means analogousto those currently implemented in known BIM systems.

FIG. 4 is a flow chart that illustrates steps for vertical spatialstratification of a volume of space into a vertical stack of horizontallayers by an improved building-information management system 200 inaccordance with embodiments of the present invention. FIG. 4 containssteps 400-450, which may be performed by embodiments that incorporatecomponents and topologies of FIGS. 1 and 2.

In step 400, airflow module 210 of BIM system 200 receives a set of windspeed and direction measurements. Each received measurement identifies awind speed v and a wind direction d at a point within thethree-dimensional volume of space that is being analyzed. Eachmeasurement thus identifies a measured wind vector (v,d) collected at apoint identified by coordinates (x,y,z).

These measurements may be collected and forwarded to the system 200 byany means known in the art. For example, measurements may be collectedby hand at various points in space by means of handheld wind meters. Inother cases, measurements may be collected by means of automatedInternet of Things sensors connected through a network to a measurementapplication. Measurements may be made using electronic meters, sensorsor anemometers mounted to the exteriors of buildings or other types ofphysical structures, or mounted on airborne devices, such as a drone oran inflatable device.

Embodiments of the present invention are flexible enough to accommodateany sort of sampling density desired by an implementer. For example, ameasurement may be collected at each window of each building erected inthe volume of space, one measurement may be collected at each floor ofeach building in the volume, or a measurement may be made at each vertexof a 1 m grid in the horizontal xy plane, and at each 5 m interval alongthe vertical z axis. An implementer may choose a custom sampling densityand pattern based on technical, cost, or resource constraints, or as afunction of a desired degree of accuracy or precision. In general, agreater measurement density will produce more accurate and preciseresults in steps 330-360, but will require greater computing resources.

Depending on embodiment-specific details, a (v,d) wind measurement mayspecify a wind speed in an “up” or “down” direction along the vertical zaxis, a wind speed in a horizontal direction relative toNorth-South-East-West compass points, or a wind speed inthree-dimensional space unconstrained in any direction. The embodimentsand examples described in this document will, for the sake ofsimplicity, comprise only horizontal wind directions, but this shouldnot be construed to restrict the present invention only to horizontalwind directions.

In step 410, the BIM airflow module 210 determines relative similaritiesamong the values of each retrieved (v,d) wind speed and direction. Thisdetermination may be accomplished by any means known in the art, or by acombination of known means.

For example, the similarity between two (v,d) measurements may bequantified by determining a Euclidean distance between the twomeasurements, by performing a Cosine Similarity operation upon the twomeasurements, or by a averaging the results of these two metrics.

In other embodiments, other mathematical methods of identifyingsimilarity may be used, and other methods of combining multiplesimilarity metrics may be used. For example, if three similarity scoresare derived by three distinct computational methods, an overallsimilarity value may be determined by weighting each score according toan implementer's judgment of the relative accuracy of each computationor of the relative relevance of each score, and then adding or averagingthe three weighted scores.

In step 420, the module 210 sorts the (v,d) measurements into layers,where each layer contains similar (v,d) measurements. Deeming twomeasurements to be similar may be performed by determining that thesimilarity determinations of step 410 produced a similarity value thatexceeds a preselected threshold value.

The threshold value may be selected by any means known in the art,including by means of expert knowledge of a person skilled in the art.Embodiments of the present invention are flexible enough to accommodateany such selection. For example, a software designer familiar withbuilding-information management applications may, through trial anderror or through educated estimations, empirically select a thresholdvalue that results in a number of layers large enough to provide asatisfactory degree of precision but small enough to require a practicalcomputational load. In other cases, a machine-learning component or aconvolutional neural network may, through mechanisms known in the art,automatically identify a threshold value that most consistently producesthe compromise between computational load and accuracy of results.

In step 430, the module 210 sets a height range for each layer. Thisstep is performed by identifying the maximum and minimum z-axis heightsassociated with the (v,d) measurements comprised by each layer. Forexample, if Layer 1 contains three (v,d) measurements collected at(x,y,z) coordinates (10 feet, 12 feet, 25 feet), (9 feet, 12 feet, 32feet), and (10 feet, 11 feet, 2 feet), the height of Layer 1 would bedeemed to extend from 2 feet (the lowest z coordinate of a (v,d)measurement comprised by Layer 1) to 32 feet ((the highest z coordinateof a (v,d) measurement comprised by Layer 1).

In step 440, module 210 reconciles any inconsistencies between the layerheight ranges derived in the previous step.

For example, if two layers overlap in height, a compromise boundary isselected as a midpoint of the overlap range. For example, if a heightrange of Layer 1 is [2,32] and the height range of Layer 2 is [28,40],the boundary between the two would be set equal to (28+32)/2=30. Theresulting height range of Layer 1 would then be [2,30] and the heightrange of Layer 2 would be [30,40].

A similar averaging procedure may be used to reconcile the height rangesof two adjacent layers if there is a gap between the height ranges ofthe two layers. For example, if a height range of Layer 1 is [2,32] andthe height range of Layer 2 is [36,40], the boundary between the twowould be set equal to (32+36)/2=34. The resulting height range of Layer1 would then be [2,34] and the height range of Layer 2 would be [34,40].

Given the real-world properties of wind currents, it is unlikely thatone layer would span a first height range that is a proper subset of asecond layer's second range or that two layers would span identicalheight ranges. If such a configuration results, analysis of such datawould fall outside the scope of the present invention. In such cases,embodiments of the present invention would continue the method of FIG. 4by returning to step 400, in order to retrieve additional measurementdata capable of resolving such unlikely inconsistencies.

In optional step 450, module 210 confirms that the verticalstratification of the volume of space into layers has resulted in adivision of the volume into a set of vertical layers, such that eachlayer contains a set of (v,d) measurements that are sufficiently similarto each other and that are sufficiently dissimilar to measurements inother layers.

This confirmation may be performed by any means known in the art. Forexample, a “t-test” (also known as a “student T-test”), which determinesand quantifies a degree of similarity between two populations may beused to determine a degree of similarity between a set of (v,d) valuesof a first layer and the total population of (v,d) measurementsretrieved in step 400. By performing this mathematical procedure on eachlayer, it is possible to determine whether a layer contains values thathave been selected with too much or too little similarity to each other.A t-test may also detect the presence of any outlier measurements thathad not been clustered into any layer in step 410 because the outliermeasurements were not sufficiently similar to measurements in any layer.

If the determination performed in this step reveals that the heightranges of the layers have not been selected to provide sufficientlysimilarity among measurements located in the same layer, and have notbeen selected to provide sufficient dissimilarity between measurementslocated in different layers, then the method of FIG. 4 may return tostep 400 or 410, to either retrieve additional measurement points, or torepeat the determination of relative similarity of measurement valueswith threshold values lowered such that measurement vectors in the samelayer are required to be have greater similarity.

Similarly, if the system in step 450 determines that the layers are toolarge, thus containing measurements that are not similar enough to eachother, the threshold value might be incrementally reduced, such that agreater degree of similarity is required in order to include two“similar” vectors in the same layer. And if the system in step 450determines that there are too many layers, resulting in measurementscomprised by one layer being too similar to measurements comprised byanother layer, the threshold values might be incrementally increased,such that a layer is allowed to include measurement vectors that areless similar to each other.

At the conclusion of the method of FIG. 4, a set of previously obtainedpairs of wind-speed and wind-direction measurements will have beenorganized by height into vertically stacked horizontal layers, such thatthere is no significant difference among wind-speed and direction valueswithin the same layer.

Certain computational steps of FIG. 4 may be illustrated by thefollowing example:

In step 400, a set of measurement vectors (v,d), including a specificpair of vectors V1(v1,d1) and V2(v2,d2), are retrieved from measurementsdatabase 212.

In step 410, the relative similarity of each pair of retrieved vectorsis determined by means of two different mathematical procedures known inthe art: a calculation of the Euclidean Distance between the twovectors, and a Cosine Similarity test, which determines similarity as afunction of the cosine of the angle between the two vectors. Theexemplary embodiment will then quantify the similarity between the pairof vectors as the average of the results of these two computations anddeem the two vectors similar if the resulting similarity value is lessthan an empirically determined threshold value of 0.5.

In this example, a Cosine Similarity of the vector pair CS(V2,V2) mayequal 0.4 and a Euclidean Distance between vector V1 and vector V2 maybe computed to equal 0.3. The average between the two would be(0.4+0.3)/2=0.35, which is less than the threshold value 0.5, indicatingthat measurements (v1,d1) and (v2,d2) are similar enough to be includedin the same layer.

Once all sampled (v,d) measurements have been sorted into layers, thesystem may optionally double-check whether the measurements in eachlayer are indeed similar to each other and dissimilar to measurements inother layers. If desired, this step may be performed by any means knownin the art, such as by subjecting the measurements in each layer to astudent t-test computation.

For example, the system may use a t-test to determine whether the sampleX={(v1,d1), (v2, d2), . . . (vn,dn)} of n (v,d) measurements comprisedby Layer 1 is sufficiently similar to the entire population of (v,d)measurements retrieved in step 400. This could be performed for Layer 1by means of the equation:

$t = {\frac{Z}{s} = \frac{\left( {\overset{\_}{X} - \mu} \right)/\left( {\sigma/\sqrt{n}} \right)}{s}}$

X is the mean value of the n (v,d) values contained in Layer1, μ is themean value of the entire population of retrieved measurements, σ is thestandard deviation of the entire population of retrieved measurements,and s is the ratio of the standard deviation of the sample population Xdivided by the standard deviation of the entire population of retrievedmeasurements. This computation results in a relative similarity t of themeasurements of Layer 1 to the total population of retrievedmeasurements.

In this example, if t is greater than a t-test threshold value of 0.5,then the t-test would have determined that the (v,d) measurementscomprised by Layer 1 are, on whole, unacceptably similar to othermeasurements of the entire set of retrieved measurements. In that case,some embodiments would then repeat earlier steps of FIG. 4 with morestringent similarity thresholds in order to ensure that the measurementscontained in a layer have greater similarity to each other.

At the conclusion of steps 430 and 440, which adjust the height rangesof each resulting layer, the airflow module 210 performs a t-testcomputation upon each pair of layers. In each computation, the t-testdetermines the overall similarity or dissimilarity between a populationof measurements of one of the layers and the overall population ofmeasurement points retrieved in step 400. In addition to revealingwhether the layers have been stratified optimally, this test will detectthe presence of any outlier measurements that were not included in anylayer in step 410 because the outlier measurements were not sufficientlysimilar to any other measurements.

FIG. 5 is a flow chart that illustrates steps for partitioning apreviously generated horizontal layer in accordance with embodiments ofthe present invention. FIG. 5 contains steps 500-550, which may beperformed by embodiments that incorporate components and topologies ofFIGS. 1 and 2.

The method of FIG. 4 previously stratified a volume of space into avertically stacked set of horizontal layers, and then divided a set of(v,d) wind measurements among the layers, such that each layer containssimilar measurement values. This procedure assumes that the windmeasurements vary monotonically and continuously along the vertical zaxis, such that measurement values within a continuous range werecollected at coordinate points that fall within a continuous range ofheights within the volume of space. Therefore, when further processing aparticular layer's population of measurements, that layer's measurementsmay be processed without the need to account for the vertical zcomponent of each measurement's three-dimensional coordinates.

The method of FIG. 5 performs an analogous procedure for each horizontallayer by dividing each layer into a grid of cells. Unlike the verticalstratification procedure, however, this horizontal division is performedto account for the effect that the density of buildings and otherstructures, located within the layer's height range, asserts on airflowcharacteristics like wind propagation, diffusion, and decay rate. Forexample, the efficiency of wind propagation can be high in an area wherephysical structures are widely dispersed, but may decrease rapidly asincreasing building-density results in a higher density of physicalstructures capable of interrupting or diverting airflows.

Each rectangular cell in a particular layer's grid may have differentdimensions in the x-y plane, but all cells within the same layer have aheight equal to the height of that layer. Wind-speed and wind-directionmeasurements that are located within the same cell will have similar(v,d) values and will have been collected at collection points where thedensity of physical structures matches the specific density associatedwith the entire cell.

The method of FIG. 5 thus uses known density based clustering algorithms(such as the known DBSCAN computation) to cluster measurements in alayer into cells as a function of the geographical location of buildingsin the volume of space and within the range of heights associated withthe layer.

Step 500 begins an iterative procedure of steps 500-550, which isrepeated once for each horizontal layer, of the volume of space,generated in FIG. 4.

In step 510, airflow analysis module 210 retrieves a list of thegeographical locations and, in some embodiments, the physical dimensionsof buildings, infrastructure elements, and other physical structureswithin the volume of space. This information is sufficient to identifythe density of these structures within an xy-plane cross-section of thevolume of space in the height range of the layer currently beingprocessed by the method of FIG. 5.

In step 520, the airflow module 210 groups the building and structurelocation data into clusters, where each cluster contains locations thatare more closely packed together in space on the current layer. Becauseall entities comprised by a particular layer are deemed to be located atsimilar heights, this clustering may be performed solely in the xydimension.

Any spatial clustering means known in the art may be used for this step.In one example, step 520 may be performed by performing a known DBSCAN(density-based spatial clustering of applications with noise) algorithmupon a subset of the building data retrieved in step 500, wherelocations specified by the subset each comprise a z-axis coordinate thatfalls within the height range of the current layer.

In step 530, airflow module 210 represents each cluster as a rectangularcell in the xy plane that has a height equal to the height range of thecurrent cluster. Each cell has x and y dimensions sufficient to comprisethe xy coordinates of all buildings located within the area of therectangular cell.

In step 540, airflow module 210 fills in the gaps between the cellscreated in step 530 with a cell that is devoid of physical structures.

In step 550, airflow module 210 organizes the cells created in steps 530and 540 into a two-dimensional grid that may cover, the entirecross-sectional area of the current layer in the (xy) plane. Each cellin this grid may contain measurement values (v,d) retrieved in step 400that have (x,y) coordinates falling within the boundaries of that celland a y coordinate that falls within the height range of the layer.

At the conclusion of the final iteration of the method of FIG. 5, eachlayer will have been further divided by this procedure into a grid ofrectangular cells. Cells of a particular grid may differ in size andaspect ratio, and each layer's grid may be distinct from grids ofadjacent layers.

The DBSCAN algorithm divides the area into clusters per the density, andmore concentrated buildings are divided into one cluster. Each clusteris abstracted into a square cell, and for the area between adjacentcells using new square cell filling, and so on. Then we get a group ofcells in the entire simulation layer. Because of different cell size, westore the cell information as a graph, as well as the adjacent cellinformation.

FIG. 6 is a flow chart that illustrates steps for generating propagationand diffusion values for cells and layers of a previously generatedhorizontal layer in accordance with embodiments of the presentinvention. FIG. 6 contains steps 600-660, which may be performed byembodiments that incorporate components and topologies of FIGS. 1 and 2.

The method of FIG. 6 determines “ventilation rates” for each grid cellon each layer, where each cell's ventilation rate identifies arelationship between airflows blowing into the cell and airflows blowingout of the cell in each north, south, east, or west horizontaldirection. For example, a higher ventilation rate along the north axismeans that a larger portion of a northerly wind entering a cell ispropagated as an outgoing airflow exiting the cell in the samedirection.

In real-world applications, input and output wind speeds may fluctuatewildly, making it difficult to accurately quantize a cell's input windspeeds and output wind speeds in real-time, or to estimate input andoutput wind speeds as functions of empirical measurements. Wind-speeddecay rates, for example, can depend greatly upon the orientation ofadjacent buildings. An east-west wall affects the decay rate ofnorth-south wind in a manner greatly different from the way that thewall affects the decay rate of east-west wind.

Embodiments of the present invention thus use a multi-step procedure toestimate and refine ventilation rates of a larger volume of air, byfirst estimating directional decay rates of each rectangular cell withina horizontal layer, refining the cellular rates by means of knowntechniques of machine learning that model input and output speeds anddecay rates as functions of attributes of the cell and its internalstructures, aggregating the cellular rates to generate layer-wideproperties, and then combining the layer-specific properties into a setof directional characteristics of the entire air volume. The resultingmodels will then automatically derive outgoing wind vectors of a volumeof air as a function of an incoming airflow.

At the conclusion of the method of FIG. 6, the system will have deriveda set of directional input and output wind vectors for every cell atcontinuous points in time. These vectors may be aggregated in order todetermine dynamic wind-propagation characteristics of the entire layer,which will then be further combined by the method of FIG. 7 to derivepropagation and diffusion characteristics of the entire volume of space.

Step 600 begins a top-level iterative procedure of steps 600-660, whichis repeated once for each horizontal layer generated in FIG. 4.

Step 610 begins an inner-nested iterative procedure of steps 600-650,which is repeated once for each cell of the horizontal layer currentlybeing processed by the top-level iterative procedure of steps 600-660.

In step 620, the airflow analysis module 210 of a BIM system 200retrieves, from attributes database 214, attribute data for the cellcurrently being processed. This attribute data may comprise:

-   -   cell attributes, such as the total area of the cell or the        cell's location or linear dimensions;    -   object attributes that identify characteristics of        three-dimensional objects located within the cell. These        characteristics may, for example, comprise an object type        (identifying an object as a building, physical infrastructure        component, and other type of physical structure) or an object's        dimensions, orientation, or location;    -   object projection areas, which identify the surface area of a        shadow-like two-dimensional projection of a three-dimensional        object, located within the cell, onto the xy, xz, or yz plane;        these projections simplify the modeling of the physical effects        of airflow components flowing in a north, south, east, or west        direction; and    -   object ventilation ratios, which identify a ratio between an        output airflow of an object located within the cell and an input        airflow of the same object. For example, a ventilation ratio of        a solid wall of an apartment building ventilation would be 0,        signifying that none of an input airflow penetrates the wall;        while a ventilation ratio of a trellis-like structure might be        0.95, identifying that 95% of the input wind blowing onto the        trellis passes through the structure.

In certain embodiments, other attributes, as might be required byimplementation-specific details, may also be retrieved from theattributes database 214.

In step 630, the airflow analysis module 210 of a BIM system 200estimates a set of directional wind-speed decay rates rate_(i) for eachcell, i∈{north, south, east, west}, using equations analogous to orsimilar to Equation (1):

$\begin{matrix}{{rate}_{i} = {\frac{\left( {{speed}_{out} - {speed}_{in}} \right)}{{speed}_{in}} \times 100\%}} & (1)\end{matrix}$

In this equation, speed_(out) is the output wind speed of airflowstraveling out of the cell along the i direction, and speed_(in) is theinput wind speed of airflows traveling into the cell along the idirection. Each input wind speed or output wind speed is selected from(v,d) wind-speed measurements collected at locations within theboundaries of the cell and closest to a boundary of the cell. Ifmultiple measurements exist on or within close proximity to a boundary,the highest magnitude measurement in each direction is selected.

For example, if three (v,d) measurements located on boundaries of a cellidentify values: (10,east), (−3,east), and (2,east), module 210 wouldselect a speed_(out) value for easterly windflow of 3 (thehighest-amplitude outgoing easterly wind speed) and a speed_(in) valuefor easterly windflow of 10 (the highest-amplitude incoming easterlywind speed).

Equation (1) would thus derive an easterly decay rate equal to:rate_(East)=(3−10)/10×100%=−70%

meaning that structures within the cell attenuate easterly winds by 70%.

Note that, in some embodiments, decay rates of inverse airflowdirections are always complementary. That is, a 40% decay rate in theeasterly direction would imply a −40% decay rate in the westerlydirection. In other embodiments, however, (v,d) measurements thatdecouple wind speeds in inverse airflow directions (that is,measurements that, for example, represent an easterly v value of −30 asa value of +30 in the westerly direction) may reveal asymmetries, suchthat a 40% easterly decay rate may not automatically imply a −40%westerly decay rate, or may not automatically imply such a conclusionunless no westerly airflow measurements exist. Such results may bederived in embodiments capable of accounting for more complexinteractions among airflows around physical objects located within acell.

In some embodiments, airflow module 210 may also use certain elements ofthe attributes and other information retrieved from attributes database214 to further refine the decay rates determined in step 630. Manyembodiments, however, including those cites as examples in thisdocument, generate mere first-order estimates of decay rates in step630, assuming a simplified model of the area within a cell, whereinairflow speeds are consistent over time and the cell contains at mostsparsely distributed physical structures that have little effect onairflows.

In step 640, the airflow module 210 uses known methods of artificialintelligence to infer relationships between the retrieved cellattributes and the cell's wind-speed decay rates. These methods maycomprise a combination of cognitive and computational methods, such asconvolutional neural networks, back-propagation neural networks,machine-learning methodologies, or cognitive methods of analytics.

In particular, some embodiments may use the known technology ofconvolutional neural networks (CNNs) to make such inferences. In suchcases, the airflow module 210 might submit to an input layer of a CNNthe previously selected most-significant input and output wind speedsand the attributes retrieved from the attributes database 214. The CNNwould then determine how the resulting wind-speed decay rates relate tothe attributes. When fully trained, after performing this processnumerous times for multiple cells, the CNN would begin to learn how todetermine a cell's wind-speed decay rates as a function of attributes ofobjects within the cell.

In step 650, the airflow module 210 uses known methods of data mining orartificial intelligence, such as machine learning, to infer associationrules that define, as functions of the retrieved cell attributes and(v,d) measurements, the cell's effect on the direction of airflowspassing through the cell. Here, each association rule associates aninput wind traveling in a first direction with a likelihood that objectswithin the cell will redirect the input wind to a second, output,direction.

These methods may also comprise a combination of other types ofcognitive and computational methods, such as convolutional neuralnetworks, back-propagation neural networks, and cognitive analytics.

Embodiments of the present invention may simplify this inferentialprocedure by assuming that characteristics of wind direction within acell are sole function of the attributes, density, and locations of theobjects within in the cell, making those characteristics relativelystatic, regardless of the speed or direction of incoming airflows.

This assumption allows a neural network or other cognitive applicationto more easily develop association rules that associate a cell's inputwind directions with the cell's output wind directions. Each discoveredrule associates a wind direction into a cell with a wind direction outof a cell, along with other parameters that are known in the art to berelated to association rules, such as a “support” value, which (given anassociation rule stating that first input wind direction into a cellgives rise to a first output wind direction out of a cell) identifieshow frequently the first input wind direction appears in the entire dataset of wind-direction values submitted to the neural network; and a“confidence” value that indicates how often the association rule isfound to produce accurate results.

At the conclusion of this step, the airflow module 210 will haveinferred a set of association rules that associate one of the forpossible input wind directions capable of blowing into a cell with anoutput wind direction blowing out of the cell. In some embodiments,multiple association rules may be associated with the same input winddirection, where each rule is characterized by a confidence factor thatindicates a likelihood that the rule correctly associates the input winddirection with an associated output wind direction.

The rules and inferred relationships generated by steps 640 and 650 thusdefine a function or model that determines how an input wind enteringthe current cell with a distinct input speed and velocity will betransformed while passing objects within the cell into an output windthat has a distinct output speed and direction.

In step 660, the airflow module 210 combines the wind-speed propagationand wind-direction characteristics of airflows entering the entire layercurrently being processed by the outer iterative procedure of steps600-660. Airflow module 210 performs this task as a function of thedecay rates and association rules derived for each cell of the currentlayer during the previous iterations of the inner nested loop of steps600-650.

Steps 600-650 have already derived decay rates in all four directionsfor every cell on the current layer and have already derived associationrules that identify the direction of an output wind flowing out of eachcell as a function of the directions of input wells flowing into thatcell. Therefore, if the input wind vectors of a cell, in all fourdirections, are known, the previously derived decay rates andassociation rules allow the cell's output wind speed and direction to bedetermined.

Because a cell can only receive airflows from adjacent cells, airflowmodule 210 in this step determines a cell's input wind speed anddirection by summing the output wind speed of each neighbor cell in eachdirection. This allows new output wind speeds and output wind directionsto be derived for cells along an edge of the layer, so long as even asingle (v,d) wind vector identifies an initial, measured, input windspeed and input wind direction along the edge of the layer.

Once new output-wind vectors have been derived for one or more cellsalong that edge of the layer, this procedure is repeated for the one ormore cell's neighbors, using the one or more cell's newly derived outputwind-speed and output wind-direction values (v,d) as input wind vectorsfor the neighbors. The airflow module 210 then, as before, derives newoutput-wind vectors for each neighbor. This process continuesiteratively across the entire layer until new output wind values havebeen derived for every cell in the layer.

In some embodiments, a particular cell may be adjacent to more than onecell that propagates an airflow into the particular cell in a certaindirection. In such cases, implementers may choose to set the particularcell's input wind speed in that direction equal to thegreatest-magnitude airflow of those propagated airflows. In otherembodiments, an implementer may choose to set the particular cell'sinput wind speed in that direction to the sum of all the airflowspropagated by adjacent cells in that direction.

At the conclusion of these actions, some embodiments of airflow module210 may then optionally repeat all of step 660 for the entire layer,using each cell's newly revised output wind vectors to derive the nextgeneration of wind vectors at the next point in time. By continuallyrepeating this procedure, the embodiment may derive a dynamic,time-varying model of the layer's airflows through a period of time, andwhere each iteration of step 660 generates a new set of airflows thatoccur during the next unit of time, as a function of the airflowsgenerated during the previous iteration. In other embodiments, thisrepeating may be performed at the conclusion of the procedure of FIG. 7in order to develop a time-varying model of the wind propagation anddiffusion characteristics of the entire volume of air, rather thanmerely of a single layer.

At the conclusion of the last iteration of the outer iterative procedureof steps 600-660, the airflow module 210 will have derived an analogousairflow propagation and diffusion module for each layer in the volume ofspace.

FIG. 7 is a flow chart that illustrates steps for aggregatingpropagation and diffusion values for each horizontal layer of a volumeof space into a regional airflow model of the entire volume. FIG. 7contains steps 700-770 which may be performed by embodiments thatincorporate components and topologies of FIGS. 1 and 2.

In step 700, airflow module 210 divides an xy-plane cross-section of thevolume of space into a set of smaller regions. In some embodiments,these divisions may comprise a grid of rectangular areas, where all therectangular areas have the same linear dimensions. In other embodiments,these divisions may comprise a grid that is similar or identical to thegrid of heterogeneous cells previously generated on one of thehorizontal layers, such as the uppermost layer, or the lowermost layer.The present invention is flexible enough to accommodate any sort ofmethod of defining the total number of regions, the density of theregions within the cross-section, the location of each region in the xyplane, and the linear dimensions of each region, as desired by animplementer. In all cases, however, the regions may not overlap and mustcover all cross-sectional areas of the volume of space for which aninput wind or output wind has been derived.

Step 710 begins an iterative procedure of steps 710-720, which isperformed once by airflow analysis module 210 for each layer of thevolume.

In step 720, airflow module 210 identifies which regions, defined instep 710, share horizontal xy space with each cell of the current layer.

At the conclusion of the last iteration of the iterative procedure ofsteps 710-720, the airflow module 210 will have identified one or morecells on each horizontal layer that correspond to each cross-sectionalregion identified in step 700.

Step 730 begins an iterative procedure of steps 730-760, which isperformed once by airflow analysis module 210 for each horizontalxy-plane of the cross-section of the volume of space selected in step700.

In step 740, airflow module 210 aggregates the results of each iterationof the procedure of steps 710-720 for the current region, identifyingall vertically stacked cells of all layers that overlap the region inhorizontal xy space.

In step 750, airflow module 210 uses known methods of vector addition tosum the input airflows of the vertically stacked cells identified instep 740. This sum identifies the input wind speed and input winddirection of the entire vertical column of the volume of space thatfalls within the horizontal xy coordinates of the region.

In step 760, airflow module 210, in a similar manner, uses known methodsof vector addition to sum the output airflows of the vertically stackedcells identified in step 740. This sum identifies the output wind speedand output wind direction of the entire vertical column of the volume ofspace that falls within the horizontal xy coordinates of the region.

At the conclusion of the last iteration of the iterative procedure ofsteps 730-760, the airflow module 210 will have determined input windvectors and corresponding output wind vectors for every horizontalregion of the volume of space. In effect, the input and output windvectors of every layer will have been combined to form a set ofheight-independent decay rates, propagation functions, and diffusionfunctions.

In step 770, the airflow module 210 uses steps analogous to those ofFIG. 6 to generate a regional airflow model of the entire volume ofspace. When provided with one or more external input wind vectors, thismodel may be used to determine airflow characteristics throughout the xyplane of the volume of space, in order to automatically generate outputwind vectors.

In a manner analogous to the method of FIG. 6, this model may be used togenerate dynamic wind propagation and diffusion characteristics byiteratively deriving multiple generations of output wind vectorsthroughout a duration of time.

This model may also be used by downstream modules of the BIM system 200for functions like “what-if” analyses and airflow optimizations, inorder to facilitate the design of buildings and of building models thatoptimize a planned building's effect on external airflows and the effectof external airflows on performance characteristics of the building.This information may, for example, allow the BIM 200 to more accuratelyselect a location, orientation, and dimensions of a planned building inorder to avoid undesirable environmental effects, or allow the BIM 200to design a building with more efficient ventilation systems, air ducts,and external vent placement.

Examples and embodiments of the present invention described in thisdocument have been presented for illustrative purposes. They should notbe construed to be exhaustive nor to limit embodiments of the presentinvention to the examples and embodiments described here. Many othermodifications and variations of the present invention that do not departfrom the scope and spirit of these examples and embodiments will beapparent to those possessed of ordinary skill in the art. Theterminology used in this document was chosen to best explain theprinciples underlying these examples and embodiments, in order toillustrate practical applications and technical improvements of thepresent invention over known technologies and products, and to enablereaders of ordinary skill in the art to better understand the examplesand embodiments disclosed here.

What is claimed is:
 1. A building-information management systemcomprising a processor, a memory coupled to the processor, and acomputer-readable hardware storage device coupled to the processor, thestorage device containing program code configured to be run by theprocessor via the memory to implement a method for abuilding-information management system with directional wind propagationand diffusion, the method comprising: the processor receiving a set ofwind vectors that have been measured concurrently at a set ofmeasurement points located within a volume of air, where each windvector of the set of wind vectors specifies a value of a horizontal windspeed at a corresponding measurement point of the set of measurementpoints and a value of a horizontal wind direction at the correspondingmeasurement point; the processor stratifying the volume of air into avertical stack of contiguous, non-overlapping horizontal layers, whereeach layer of the stack extends through a contiguous range of verticalheights and encompasses a subset of the set of measurement pointsmeasured at heights within that layer's range of vertical heights; theprocessor retrieving a set of building attributes that identifylocations and physical dimensions of buildings located within the volumeof space; the processor dividing each layer of the horizontal layersinto a horizontal grid of rectangular cells, where a first cell of afirst layer of the horizontal layers encloses horizontal cross-sectionsof a first subset of the buildings at heights within the first layer'srange of vertical heights; the processor selecting, as a function ofthose received wind vectors that were measured at measurement pointscomprised by the first cell, an input wind speed of the first cell ineach horizontal wind direction and an output wind speed of the firstcell in each horizontal wind direction, where each horizontal winddirection is selected from the group consisting of northerly, southerly,easterly, and westerly, and where the selecting an input wind speed ofthe first cell in each horizontal wind direction and an output windspeed of the first cell in each horizontal wind direction furthercomprises: the processor identifying a first subset of the set ofmeasurement points and a second subset of the set of measurement points,where the first subset and the second subset both consist of measurementpoints located along boundaries of the first cell, where each windvector measured at a measurement point of the first subset specifieswind traveling into the first cell parallel to a first direction of thegroup of horizontal wind directions, and where each wind vector measuredat a measurement point of the second subset specifies wind traveling outof the first cell parallel to the first direction; the processor settingan input wind speed of the first cell in the first direction equal to ahighest-magnitude wind speed specified by any wind vector measured at ameasurement point of the first subset; the processor choosing an outputwind speed of the first cell in the first direction equal to ahighest-magnitude wind speed specified by any wind vector measured at ameasurement point of the second subset; and the processor repeating theidentifying, the setting, and the choosing for each of the remainingthree directions of the group of horizontal wind directions; theprocessor inferring relationships between wind-speed decay rates ofhorizontal winds flowing through the first cell and retrieved attributesof buildings that are at least partially enclosed by the first cell; andthe processor forwarding to downstream modules of thebuilding-information management system a wind-propagation model of thevolume of space that identifies, as a function of the inferredrelationships, rules for determining wind vectors of winds exiting thevolume as functions of wind vectors of winds entering the volume.
 2. Thesystem of claim 1, where measurement points comprised by the first layerof the horizontal layers correspond to a first set of measured windvectors, where all values of the first set of measured wind vectors aresimilar, and where no value of the first set of measured wind vectors issimilar to a value of a wind vector associated with a measurement pointcomprised by a different layer of the horizontal layers.
 3. The systemof claim 2, where two wind vectors are deemed to be similar if aEuclidean distance between the vectors does not exceed a predeterminedthreshold value.
 4. The system of claim 2, where two wind vectors aredeemed to be similar if a Cosine Similarity of the two wind vectors doesnot exceed a predetermined threshold value.
 5. The system of claim 1,where boundaries of each cell are chosen such that each cell enclosescross-sections of an entire cluster of buildings and enclosescross-sections of no other buildings, and where buildings are organizedinto clusters by application of a DBSCAN (density-based spatialclustering of applications with noise) algorithm to the buildingslocated within the volume of space.
 6. The system of claim 1, where theemploying further comprises: the processor inferring a set ofassociation rules that each specify that winds entering the first cellfrom a triggering input-wind direction must exit the first cell from anassociated output-wind direction, where the triggering input-winddirection and the associated output-wind direction are both selectedfrom the group of horizontal wind directions; and the processorincorporating the association rules into the wind-propagation model. 7.The system of claim 6, further comprising: the processor building alayer-ventilation model of the first layer as functions of thewind-speed decay rates, inferred relationships, and inferred associationrules of each cell of the first layer, where the layer-ventilation modelcomprises rules for determining wind vectors of winds traveling out ofthe first layer as a function of values of wind vectors of windstraveling into the layer; the processor aggregating thelayer-ventilation models of all horizontal layers of the volume into aregional ventilation model; and the processor incorporating the regionalmodel into the wind-propagation model of the volume of space.
 8. Amethod for a building-information management system with directionalwind propagation and diffusion, the method comprising: a processor ofthe building-information management system receiving a set of windvectors that have been measured concurrently at a set of measurementpoints located within a volume of air, where each wind vector of the setof wind vectors specifies a value of a horizontal wind speed at acorresponding measurement point of the set of measurement points and avalue of a horizontal wind direction at the corresponding measurementpoint; the processor stratifying the volume of air into a vertical stackof contiguous, non-overlapping horizontal layers, where each layer ofthe stack extends through a contiguous range of vertical heights andencompasses a subset of the set of measurement points measured atheights within that layer's range of vertical heights; the processorretrieving a set of building attributes that identify locations andphysical dimensions of buildings located within the volume of space; theprocessor dividing each layer of the horizontal layers into a horizontalgrid of rectangular cells, where a first cell of a first layer of thehorizontal layers encloses horizontal cross-sections of a first subsetof the buildings at heights within the first layer's range of verticalheights; the processor selecting, as a function of those received windvectors that were measured at measurement points comprised by the firstcell, an input wind speed of the first cell in each horizontal winddirection and an output wind speed of the first cell in each horizontalwind direction, where each horizontal wind direction is selected fromthe group consisting of northerly, southerly, easterly, and westerly,and where the selecting an input wind speed of the first cell in eachhorizontal wind direction and an output wind speed of the first cell ineach horizontal wind direction further comprises: the processoridentifying a first subset of the set of measurement points and a secondsubset of the set of measurement points, where the first subset and thesecond subset both consist of measurement points located alongboundaries of the first cell, where each wind vector measured at ameasurement point of the first subset specifies wind traveling into thefirst cell parallel to a first direction of the group of horizontal winddirections, and where each wind vector measured at a measurement pointof the second subset specifies wind traveling out of the first cellparallel to the first direction; the processor setting an input windspeed of the first cell in the first direction equal to ahighest-magnitude wind speed specified by any wind vector measured at ameasurement point of the first subset; the processor choosing an outputwind speed of the first cell in the first direction equal to ahighest-magnitude wind speed specified by any wind vector measured at ameasurement point of the second subset; and the processor repeating theidentifying, the setting, and the choosing for each of the remainingthree directions of the group of horizontal wind directions; theprocessor inferring relationships between wind-speed decay rates ofhorizontal winds flowing through the first cell and retrieved attributesof buildings that are at least partially enclosed by the first cell; andthe processor forwarding to downstream modules of thebuilding-information management system a wind-propagation model of thevolume of space that identifies, as a function of the inferredrelationships, rules for determining wind vectors of winds exiting thevolume as functions of wind vectors of winds entering the volume.
 9. Themethod of claim 8, where measurement points comprised by the first layerof the horizontal layers correspond to a first set of measured windvectors, where all values of the first set of measured wind vectors aresimilar, and where no value of the first set of measured wind vectors issimilar to a value of a wind vector associated with a measurement pointcomprised by a different layer of the horizontal layers.
 10. The methodof claim 8, where boundaries of each cell are chosen such that each cellencloses cross-sections of an entire cluster of buildings and enclosescross-sections of no other buildings, and where buildings are organizedinto clusters by application of a DBSCAN (density-based spatialclustering of applications with noise) algorithm to the buildingslocated within the volume of space.
 11. The method of claim 8, where theemploying further comprises: the processor inferring a set ofassociation rules that each specify that winds entering the first cellfrom a triggering input-wind direction must exit the first cell from anassociated output-wind direction, where the triggering input-winddirection and the associated output-wind direction are both selectedfrom the group of horizontal wind directions; the processorincorporating the association rules into the wind-propagation model; theprocessor building a layer-ventilation model of the first layer asfunctions of the wind-speed decay rates, inferred relationships, andinferred association rules of each cell of the first layer, where thelayer-ventilation model comprises rules for determining wind vectors ofwinds traveling out of the first layer as a function of values of windvectors of winds traveling into the layer; the processor aggregating thelayer-ventilation models of all horizontal layers of the volume into aregional ventilation model; and the processor incorporating the regionalmodel into the wind-propagation model of the volume of space.
 12. Themethod of claim 8, further comprising providing at least one supportservice for at least one of creating, integrating, hosting, maintaining,and deploying computer-readable program code in the computer system,wherein the computer-readable program code in combination with thecomputer system is configured to implement the receiving, thestratifying, the retrieving, the dividing, the selecting, the inferring,and the forwarding.
 13. A computer program product, comprising acomputer-readable hardware storage device having a computer-readableprogram code stored therein, the program code configured to be executedby a building-information management system comprising a processor, amemory coupled to the processor, and a computer-readable hardwarestorage device coupled to the processor, the storage device containingprogram code configured to be run by the processor via the memory toimplement a method for a building-information management system withdirectional wind propagation and diffusion, the method comprising: theprocessor receiving a set of wind vectors that have been measuredconcurrently at a set of measurement points located within a volume ofair, where each wind vector of the set of wind vectors specifies a valueof a horizontal wind speed at a corresponding measurement point of theset of measurement points and a value of a horizontal wind direction atthe corresponding measurement point; the processor stratifying thevolume of air into a vertical stack of contiguous, non-overlappinghorizontal layers, where each layer of the stack extends through acontiguous range of vertical heights and encompasses a subset of the setof measurement points measured at heights within that layer's range ofvertical heights; the processor retrieving a set of building attributesthat identify locations and physical dimensions of buildings locatedwithin the volume of space; the processor dividing each layer of thehorizontal layers into a horizontal grid of rectangular cells, where afirst cell of a first layer of the horizontal layers encloses horizontalcross-sections of a first subset of the buildings at heights within thefirst layer's range of vertical heights; the processor selecting, as afunction of those received wind vectors that were measured atmeasurement points comprised by the first cell, an input wind speed ofthe first cell in each horizontal wind direction and an output windspeed of the first cell in each horizontal wind direction, where eachhorizontal wind direction is selected from the group consisting ofnortherly, southerly, easterly, and westerly, and where the selecting aninput wind speed of the first cell in each horizontal wind direction andan output wind speed of the first cell in each horizontal wind directionfurther comprises: the processor identifying a first subset of the setof measurement points and a second subset of the set of measurementpoints, where the first subset and the second subset both consist ofmeasurement points located along boundaries of the first cell, whereeach wind vector measured at a measurement point of the first subsetspecifies wind traveling into the first cell parallel to a firstdirection of the group of horizontal wind directions, and where eachwind vector measured at a measurement point of the second subsetspecifies wind traveling out of the first cell parallel to the firstdirection; the processor setting an input wind speed of the first cellin the first direction equal to a highest-magnitude wind speed specifiedby any wind vector measured at a measurement point of the first subset;the processor choosing an output wind speed of the first cell in thefirst direction equal to a highest-magnitude wind speed specified by anywind vector measured at a measurement point of the second subset; andthe processor repeating the identifying, the setting, and the choosingfor each of the remaining three directions of the group of horizontalwind directions; the processor inferring relationships betweenwind-speed decay rates of horizontal winds flowing through the firstcell and retrieved attributes of buildings that are at least partiallyenclosed by the first cell; and the processor forwarding to downstreammodules of the building-information management system a wind-propagationmodel of the volume of space that identifies, as a function of theinferred relationships, rules for determining wind vectors of windsexiting the volume as functions of wind vectors of winds entering thevolume.
 14. The computer program product of claim 13, where measurementpoints comprised by the first layer of the horizontal layers correspondto a first set of measured wind vectors, where all values of the firstset of measured wind vectors are similar, and where no value of thefirst set of measured wind vectors is similar to a value of a windvector associated with a measurement point comprised by a differentlayer of the horizontal layers.
 15. The computer program product ofclaim 13, where boundaries of each cell are chosen such that each cellencloses cross-sections of an entire cluster of buildings and enclosescross-sections of no other buildings, and where buildings are organizedinto clusters by application of a DBSCAN (density-based spatialclustering of applications with noise) algorithm to the buildingslocated within the volume of space.
 16. The computer program product ofclaim 13, where the employing further comprises: the processor inferringa set of association rules that each specify that winds entering thefirst cell from a triggering input-wind direction must exit the firstcell from an associated output-wind direction, where the triggeringinput-wind direction and the associated output-wind direction are bothselected from the group of horizontal wind directions; and the processorincorporating the association rules into the wind-propagation model. 17.The computer program product of claim 16, further comprising: theprocessor building a layer-ventilation model of the first layer asfunctions of the wind-speed decay rates, inferred relationships, andinferred association rules of each cell of the first layer, where thelayer-ventilation model comprises rules for determining wind vectors ofwinds traveling out of the first layer as a function of values of windvectors of winds traveling into the layer; the processor aggregating thelayer-ventilation models of all horizontal layers of the volume into aregional ventilation model; and the processor incorporating the regionalmodel into the wind-propagation model of the volume of space.